2 Movement
2.1 Human Movement and Muscles on the Molecular Scale
In this chapter, voluntary movement is discussed. As with the human senses, human vol-
untary movement happens in response to a signal. When the signal occurs, the muscle
contracts. Depending on the muscle force needed, a different number of muscle fibers
contract. In most cases, this contraction takes place over a short time period and the
muscle will quickly return to its extended, relaxed state.
Molecularly-speaking, how does a muscle contract? A muscle contains bundles of
parallel muscle fibers called fascicles (Figure 2.1a) [1]. Each muscle fiber is actually a cell
with its own cell membrane and nucleus, as well as storage granules containing glycogen
(see 1.2, Structure and function of molecules – sugars and polysaccharides). The muscle
cell has several important special features: it contains the sarcolemma, which is a large,
membrane-covered storage space for calcium ions (in fact, there are basically no cal-
cium ions present in the cell with the exception of the calcium ions in the sarcolemma).
Additionally, the cell membrane of muscle cells is special in that it is charged, and it can
change its charge as a nerve cell does by pumping sodium and potassium ions in and
out of the cell.
The signal for contraction comes from nerve cells originating in the spinal cord. If
these nerve cells release their neurotransmitter acetylcholine, which activates ion chan-
nels in the cell membrane, ions will be released and thus the charge on the membrane
is changed (depolarization) (Figure 2.1b) [1]. As soon as the charge of the membrane
changes, calcium channels in the membrane are activated to pump a small amount of
calcium ions into the muscle cell. Those few calcium ions are sufficient to activate cal-
cium channels in the sarcolemma, which then pump many calcium ions into the muscle
cell. As seen with many signals in cells, the stepwise activation leads to the amplification
of the signal and thus a fast change, as needed for voluntary muscle contraction [2]. Now
that we have the signal, how does the signal lead to an actual force?
To understand that, another special set of features of the muscle cells must be ex-
plained: the myofilaments in the myofibrils, actin and myosin (Figure 2.1). Actin is a fiber
that is stiff and fixed in the cell. Myosin is also a stiff fiber but has a lot of heads that can
move [3]. Myosin can walk with those heads along the actin fibers and pull the whole
fibers and thus cells with it, 10 nanometers at a time (Figure 2.2). This occurs via lever
action, part of the myosin head protein being built like a lever [4–6]. So each muscle con-
traction is a combination of a lot of concurrent 10 nm lever actions all parallel to each
other and in the same direction [7].
When the muscle is at rest, the actin fiber is covered and does not allow the myosin
to bind [1]. Calcium ions in the muscle cell essentially pull the covers of the actin fibers
away, exposing binding sites for the myosin heads. The myosin heads are always acti-
vated, i. e. ready for the next pull, when the muscle is at rest. Therefore, as soon as it
is possible, the myosin heads will bind the actin fibers and move the head so that the
https://doi.org/10.1515/9783110779196-002